KR20100135534A - Ice guiding grill and ice maker having the same - Google Patents

Abstract

PURPOSE: An ice guide grill and an ice maker having the same are provided to enable the ices of an ice storage to be uniformly distributed by controlling the dropping direction of the ices, which are generated by a plurality of ice generating members and drop to the ice storage. CONSTITUTION: An ice guide grill comprises a grill body(200) and a guide unit(300). The grill body is installed between a plurality of ice generating members and an ice storage, wherein the ice generating members are located in an ice maker. The guide unit is located on the upper part of the grill body, comprises a plurality of guide ribs(310), which have different heights, and thus when the ices are separated from the ice generating members and are dropped, the guide unit adjusts the dropping direction of the ices and enables the ices to be uniformly distributed in the ice storage. The guide rib comprises a lowest guide rib(311) and a highest guide rib(312), which is higher than the lowest guide rib.

Description

ICE GUIDING GRILL AND ICE MAKER HAVING THE SAME}

The present invention relates to an ice guide grill and an ice maker having the same.

Ice maker 3 as shown in Fig. 1 is a device for making ice I. In FIG. 1, the ice maker 3 is installed in the ice water purifier 1. As shown in FIG.

Water introduced into the ice water purifier 1 is filtered through a plurality of water filters (not shown) provided in the ice water purifier 1 and stored in the water purification tank 2. In this way, the filtered water stored in the purified water tank 2 is stored in the ice tray 5 in a state where the ice tray 5 shown in FIG. 1 is rotated 90 degrees from the position shown so that the ice producing member 4 is locked. Supplied.

The refrigerant flows inside the ice making member 4. Accordingly, ice I is generated in the ice making member 4 by heat exchange between the refrigerant flowing in the ice making member 4 and the filtered water contained in the ice tray 5.

When the production of the ice I is completed in the ice making member 4, the ice tray 5 is rotated to a position as shown in FIG. Thereafter, the hot refrigerant flows inside the ice making member 4 to melt the contact surface of the ice I in contact with the ice making member 4. As a result, as shown, ice I falls by its own weight. The falling ice I is guided and stored in the ice storage 7 by the ice guide grill 10 and the guide member 9 installed below the ice producing member 4. On the other hand, in the case of guiding the ice I to the cold water tank 6, the ice I guided by the ice guide grill 10 by rotating the guide member 9 in a clockwise direction at the position shown. To the cold water tank (6).

Ice (I) stored in the ice reservoir (7) is connected to the motor (M) as shown in Figure 2 to the ice discharge port (E) by the ice extraction member (8) rotated by the drive of the motor (M) Move. Ice (I) moved to the ice discharge port (E) is discharged through the ice discharge port (E). Accordingly, as shown in the portion adjacent to the ice discharge port (E) of the ice reservoir (7) is a lot of ice (I) is stacked.

A plurality of guide ribs 31 are formed on the top of the conventional ice guide grill 10, as shown in FIG. The guide rib 31 guides the ice I generated and separated from the ice making member 4 to the ice storage 7. Conventionally, the guide rib 31 has a constant height as shown. Therefore, the ice I separated from the ice making member 4 and dropped to the guide rib 31 is not deflected in the direction of the ice discharge port E or the direction of the ice discharge port E, as shown, without being deflected. 7) will fall. Therefore, more ice I is accumulated in the portion adjacent to the ice discharge port E of the ice reservoir 7. Accordingly, there is a problem that the ice I is not evenly distributed in the ice storage 7. And, if the ice (I) is not evenly distributed in the ice storage 7 in this way, there is a problem that leakage or ice pouring may occur.

Meanwhile, as illustrated in FIG. 2, the ice reservoir 7 is provided with ice detection sensors S1 and S2 including a transmitter for transmitting a signal and a receiver for receiving a signal. Therefore, when the ice I is filled in the ice reservoir 7 and blocks the signal between the transmitter and the receiver, it is recognized that the ice reservoir 7 is full of ice I. However, as shown in FIG. 1, when ice I accumulates relatively in a portion adjacent to the ice discharge port E of the ice reservoir 7, that is, the ice I is not evenly distributed in the ice reservoir 7. If not, there is a problem in that the ice storage (7) may cause a full ice error that is recognized as full even though the ice (I) is not full.

The present invention is made by recognizing at least one of the needs or problems occurring in the conventional ice guide grill and the ice maker provided with the same.

One object of the present invention is to be able to control the falling direction of the ice is generated from a plurality of ice producing members separated by falling into the ice storage.

Another object of the present invention is to adjust the direction of the falling ice to evenly distribute the ice stored in the ice storage.

Ice guide grill associated with an embodiment for realizing at least one of the above problems may include the following features.

Embodiments related to the present invention are basically formed on the ice guide grill by forming a plurality of guide ribs having different heights based on controlling the falling direction of the ice generated in the ice producing member and separated and dropped into the ice storage.

Ice guide grill according to an embodiment of the present invention is a grill body portion installed between the plurality of ice producing member and the ice storage provided in the ice maker; A guide portion positioned at an upper portion of the grill body part and having a plurality of guide ribs having different heights so as to control the dropping direction of the ice upon separation of the ice generated from the ice generating member so that the ice is evenly distributed in the ice storage; As shown in FIG.

In this case, the plurality of guide ribs may include a minimum guide rib and a top guide rib having a higher height than the minimum guide rib.

The plurality of guide ribs may further include an intermediate guide rib having a height higher than the minimum guide rib and a height lower than the highest guide rib.

The top guide rib includes a first top guide rib positioned at a portion of the guide portion closest to an ice discharge port formed in the ice reservoir, and the first top guide rib is deflected in a direction opposite to the ice discharge port and falls. It may be located so as to deflect in the direction of the ice discharge port from the center line of the ice producing member so that the ice is generated.

The top guide rib includes a second top guide rib positioned at a part of the guide part farthest from the ice discharge port formed in the ice reservoir, and the second top guide rib is deflected in the direction of the ice discharge port. The ice may be positioned to be deflected in a direction opposite to the ice discharge port from the center line of the ice producing member in which ice is generated.

On the other hand, the highest guide ribs are the first highest guide ribs located in the portion of the guide portion closest to the ice discharge port formed in the ice reservoir, the second highest guide ribs located in the portion of the guide portion farthest from the ice discharge port, and the first And a third top guide rib positioned in the guide portion between the top guide rib and the second top guide rib, further included in the plurality of guide ribs, the height of which is higher than the minimum guide rib, the height of which is lower than the top guide rib, and the first guide rib. The intermediate guide ribs or the third top guide ribs positioned in the guide portion between the top guide ribs and the second top guide ribs are formed in the ice generating member in which ice is generated so that the ice colliding with them may be deflected in the opposite direction to the ice discharge port. It may be located to be deflected from the center line toward the ice discharge port.

Ice maker according to an embodiment of the present invention is connected to the refrigeration cycle and a plurality of ice producing member for generating ice by heat exchange with the refrigerant flowing therein; The above-described ice guide grill installed under the plurality of ice-making members so as to control the falling direction of the ice falling from the plurality of ice-making members; And an ice reservoir installed under the ice guide grill to store the ice falling from the ice guide grill. As shown in FIG.

As described above, according to an embodiment of the present invention, the falling direction of the ice generated by the plurality of ice-generating members and separated into the ice storage can be adjusted.

In addition, according to an embodiment of the present invention, by adjusting the falling direction of the ice can evenly distribute the ice stored in the ice storage.

In addition, according to an embodiment of the present invention, by evenly distributing the ice stored in the ice storage can be prevented leaks or ice spills or ice faults caused by the accumulation of ice adjacent to the ice outlet of the ice storage have.

In addition, according to an embodiment of the present invention, the ice does not collide with the side wall of the ice reservoir to prevent vibration and noise that may occur due to the ice collides with the side wall of the ice reservoir.

In order to help the understanding of the features of the present invention as described above, it will be described in more detail with respect to the ice guide grill and the ice maker provided with the same according to an embodiment of the present invention.

Hereinafter, the described embodiments will be described on the basis of the most suitable embodiments for understanding the technical features of the present invention, and the technical features of the present invention are not limited by the described embodiments. It is to be exemplified that the present invention can be implemented as in the following embodiments. Accordingly, the present invention may be modified in various ways within the technical scope of the present invention through the embodiments described below, and such modified embodiments fall within the technical scope of the present invention. And, in order to help the understanding of the embodiments described below, in the reference numerals described in the accompanying drawings, in each embodiment, the relevant components among the components that will have the same action is denoted by the same or extension number.

Embodiments related to the present invention are basically formed on the ice guide grill by forming a plurality of guide ribs having different heights, based on adjusting the dropping direction of the ice generated by the ice producing member and falling down into the ice storage.

As illustrated in FIG. 3, the ice guide grill according to the present invention may include a grill body part 200 and a guide part 300.

The grill body 200 may be installed between the ice producing member 4 and the ice storage 7 provided in the ice maker 3 as in the embodiment shown in FIG. In the illustrated embodiment, the ice maker 3 is installed in the ice water purifier 1 as shown in FIG. However, the ice maker 3 may be installed in a refrigerator or the like in addition to the ice purifier 1. In addition, unlike the ice tray 5 consisting of one drip tray as shown in FIG. 1, for example, if an ice tray (not shown) having two drip trays connected in an L shape is used in the ice maker 3, the grill body portion ( 200 may be installed on top of one of the two drip trays of this ice tray.

Meanwhile, the ice making member 4 may be connected to a refrigeration cycle (not shown). The coolant may flow inside the ice making member 4. Then, when water is supplied to the ice tray 5 in a state where the ice tray 5 shown in FIG. 1 is rotated by 90 ° from the illustrated position, the ice making member 4 is supplied to the water supplied to the ice tray 5. Will be locked. When the refrigeration cycle is operated in this state, ice (I) may be generated in the ice producing member 4 by heat exchange between the refrigerant flowing in the ice producing member 4 and the water contained in the ice tray 5. have.

The guide part 300 may be located above the grill body part 200 as shown in FIG. 3. As shown in the illustrated embodiment, the guide part 300 may be positioned above the grill body part 200 and integrally formed with the grill body part 200. However, the grill body portion 200 and the guide portion 300 may be made of a different member may be coupled by a connection member such as an adhesive, a bolt or a screw. In the guide part 300, a plurality of guide ribs 310 having different heights may be formed as in the illustrated embodiment. By the guide ribs 310, the fall direction of the ice I may be adjusted when the ice I generated by the ice making member 4 falls apart. Accordingly, the ice I may be evenly distributed in the ice reservoir 7.

The plurality of guide ribs 310 may include the lowest guide rib 311 and the highest guide rib 312 having a height higher than that of the lowest guide rib 311 as shown in FIGS. 3 and 4. . In addition, the plurality of guide ribs 310 may further include an intermediate guide rib 313 having a height higher than the lowest guide rib 311 and lower than the highest guide rib 312 as shown in the illustrated embodiment.

Meanwhile, as shown in FIGS. 3 and 4, the top guide rib 312 is a first top guide positioned at a portion of the guide part 300 closest to the ice discharge port E formed in the ice storage 7. Ribs 312a may be included. And, as shown in the embodiment shown in Figure 4, the first highest guide rib 312a is deflected in the direction of the ice discharge port (E) from the center line (C1) of the ice producing member 4, the ice (I) is generated to collide with it. Can be located. Accordingly, as shown in the embodiment shown in FIG. 4, the ice I driven therefrom may be deflected in the opposite direction of the ice discharge port E and fall. Therefore, it is possible to prevent the ice I from accumulating adjacent to the ice discharge port E.

And, as shown in the embodiment shown in Figures 3 and 4, the top guide rib 312 is the second top guide located in the portion of the guide portion 300 farthest from the ice discharge port (E) of the ice storage (7) The rib 312b may further include. And, as shown in the embodiment shown in Figure 4, the second highest guide rib (312b) is in the opposite direction to the ice discharge port (E) in the center line (C2) of the ice producing member (4), the ice (I) is generated to collide with it. Can be biased. Accordingly, as illustrated in FIG. 4, the ice I colliding therewith may be deflected and fall in the direction of the ice discharge port E. FIG. Therefore, by preventing the ice I from colliding with the side wall of the ice reservoir 7, it is possible to prevent noise and vibration that may occur due to the ice I colliding with the side wall of the ice reservoir 7.

3 and 4, the top guide rib 312 is positioned in the guide portion 300 between the first top guide rib 312a and the second top guide rib 312b. The top guide rib 312c may further include. And, as shown in the embodiment shown in Figure 4, the third highest guide rib 312c is deflected in the direction of the ice discharge port (E) from the center line (C) of the ice producing member (4), the ice (I) is generated to collide with it. Can be located. Accordingly, as illustrated in FIG. 4, the ice I colliding therewith may be deflected in the opposite direction to the ice discharge port E and fall. Therefore, it is possible to prevent the ice I from accumulating adjacent to the ice discharge port E.

3 and 4, the intermediate guide ribs 313 positioned in the guide portion 300 between the first highest guide rib 312a and the second highest guide rib 312b collide with each other. The ice I may be positioned to be deflected in the direction of the ice discharge port E from the center line C of the ice producing member 4. Accordingly, as illustrated in FIG. 4, the ice I colliding therewith may be deflected in the opposite direction to the ice discharge port E and fall. Therefore, it is possible to prevent the ice I from accumulating adjacent to the ice discharge port E.

On the other hand, in the embodiment shown in Figures 3 and 4, although one third highest guide rib 312c or intermediate guide rib 313 is formed in the guide portion 300, at least two third highest guide ribs 312c or the intermediate guide rib 313 may be formed.

One embodiment of the ice maker 3 having an ice guide grill 100 according to the present invention is an ice producing member 4 and the ice guide grill 100 according to the present invention as described in the embodiment shown in FIG. And, it may be configured to include an ice storage (7). Such an ice maker 3 may be installed in the ice water purifier 1 as shown in FIG. 1. However, it may also be installed in a refrigerator or the like.

The ice making member 4 may be connected to a refrigeration cycle (not shown). In addition, a coolant may flow in the ice making member 4. Then, when water is supplied to the ice tray 5 in a state where the ice tray 5 shown in FIG. 1 is rotated by 90 ° from the illustrated position, the ice making member 4 is supplied to the water supplied to the ice tray 5. Will be locked. When the refrigeration cycle is operated in this state, ice (I) may be generated in the ice producing member 4 by heat exchange between the refrigerant flowing in the ice producing member 4 and the water contained in the ice tray 5. have.

The ice guide grill 100 may be installed under the plurality of ice producing members (4). As described above, the ice guide grill 100 may include a grill body 200 and a guide 300 having a plurality of guide ribs 310 having different heights. In addition, the guide rib 310 may include the lowest guide rib 311 and the highest guide rib 312 as described above. In addition, the intermediate guide rib 313 may further include. Meanwhile, as described above, the top guide rib 312 may include a first top guide rib 312a, a second top guide rib 312b, or a third top guide rib 312c.

The ice reservoir 7 may be installed below the ice guide grill 100 to store the ice I falling from the ice guide grill 100. The ice reservoir 7 may be formed with an ice discharge port E through which the stored ice I is discharged as shown in FIG. 4. In addition, the ice extracting member 8 which is connected to the motor M and rotates may be provided. By rotating the ice extraction member 8, the ice I stored in the ice reservoir 7 can be moved to the ice discharge port E. And, the ice I moved to the ice discharge port (E) may be discharged through the ice discharge port (E). On the other hand, the ice reservoir (7) may be provided with an ice sensor (S1, S2) consisting of a transmitter for transmitting a signal and a receiver for receiving a signal as shown in FIG. Therefore, when the ice I is filled in the ice reservoir 7 and the ice I blocks a signal between the transmitter and the receiver, it is recognized that the ice reservoir 7 is full of ice I.

Hereinafter, with reference to Figure 5 will be described in detail the operation of the embodiment of the ice guide grill and ice maker provided with the same according to the present invention.

When the production of the ice I is completed in the ice making member 4, the ice tray 5 is rotated to a position as shown in FIG. Subsequently, when the hot refrigerant flows inside the ice producing member 4, the contact surface of the ice I in contact with the ice producing member 4 melts and the ice I falls due to its own weight. As the falling ice I collides with the guide rib 310 of the ice guide grill 100 as shown in FIG. 5, the falling direction is adjusted.

That is, in the illustrated embodiment, the ice I driven to the first top guide rib 312a is deflected in the opposite direction to the ice discharge port E and falls. In addition, the ice I collided with the intermediate guide rib 313 and the ice I collided with the third highest guide rib 312c are also deflected in the opposite direction to the ice discharge port E and fall. On the other hand, the ice I collided with the second highest guide rib 312b is deflected toward the ice discharge port E and falls.

The ice I stored in the ice reservoir 7 is rotated by the driving of the motor M connected to the ice extraction member 8. Accordingly, the ice (I) stored in the ice reservoir 7 is moved to the ice discharge port (E) is discharged through the ice discharge port (E). Therefore, a large amount of ice (I) is accumulated in the portion adjacent to the ice discharge port (E) in the ice reservoir (7).

As described above, the ice I collided with the first top guide rib 312a, the intermediate guide rib 313, or the third top guide rib 312c is deflected in the opposite direction to the ice discharge port E and is stored in the ice reservoir ( 7) will fall. Therefore, the ice I does not fall to the portion adjacent to the ice discharge port E in which the ice I is already accumulated, but the ice I falls to a part distant from the ice discharge port E. That is, the fall direction of the ice I can be adjusted so that the ice I does not fall adjacent to the ice discharge port E, so that the ice I can be evenly distributed in the ice storage 7. Therefore, it is possible to prevent leakage or ice spillage that may occur due to the accumulation of ice (I) adjacent to the ice discharge port (E) of the ice reservoir (7). In addition, ice (I) is relatively accumulated in the portion adjacent to the ice discharge port (E) of the ice reservoir (7) by blocking the signal between the ice sensor (S1, S2), ice It is possible to prevent (I) from recognizing that it is full even if it is not full.

 On the other hand, the ice I collided with the second highest guide rib 312b is deflected toward the ice discharge port E and falls. Therefore, since the ice I does not collide with the side wall of the ice reservoir 7, vibration and noise that may occur due to the ice I collide with the side wall of the ice reservoir 7 may be prevented.

The above-described ice guide grill and the ice maker including the same are not limited to the configuration of the above-described embodiment, but the embodiments may be configured by selectively combining all or some of the embodiments so that various modifications may be made. May be

1 is a view showing a conventional ice maker installed in an ice water purifier and a conventional ice guide grill provided in the ice maker, and guides the ice generated by the ice producing member of the ice maker to the ice drop by the ice guide grill. It is a figure which shows.

FIG. 2 is a cross-sectional view taken along line AA ′ of FIG. 1.

Figure 3 is a perspective view of one embodiment of an ice guide grill according to the present invention.

Figure 4 is an ice maker provided with an embodiment of the ice guide grill according to the present invention, and a view showing the falling direction of the ice according to one embodiment of the ice guide grill according to the present invention.

Figure 5 is produced by the ice producing member of the ice maker according to one embodiment of the ice guide grill according to the present invention in an ice maker equipped with an embodiment of the ice guide grill according to the present invention by adjusting the falling direction of the falling ice The figure shows an even distribution of ice in the reservoir.

             Explanation of symbols on the main parts of the drawings

1: ice water purifier 2: water purification tank

3: ice maker 4: ice making member

5: ice tray 6: cold water tank

7: ice storage 8: ice extraction member

9: guide member 10, 100: ice guide grill

200: grill body 300: guide

31, 310: Guide rib 311: Minimum guide rib

312: Top guide rib 312a: First top guide rib

312b: 2nd highest guide rib 312c: 3rd highest guide rib

313: intermediate guide rib I: ice

C, C1, C2: centerline E: ice discharge outlet

M: Motor S1, S2: Ice Sensor

Claims (7)

A grill body part 200 installed between the plurality of ice making members 4 and the ice storage 7 provided in the ice maker 3; A plurality of guide ribs 310 formed on the grill body 200 and having different heights are formed to separate and separate the ice I generated by the ice making member 4 from the ice I. A guide part 300 to adjust the falling direction of the ice reservoir 7 to distribute the ice (I) evenly; Ice guide consisting of grills. The ice guide grill according to claim 1, wherein the plurality of guide ribs 310 includes a minimum guide rib 311 and a top guide rib 312 having a height higher than that of the minimum guide rib 311. . The plurality of guide ribs 310 further includes an intermediate guide rib 313 having a height higher than that of the lowest guide rib 311 and lower than that of the top guide rib 312. Guide the ice to draw. The first guide rib 312a according to claim 2, wherein the top guide rib 312 is positioned at a portion of the guide portion 300 that is closest to the ice discharge port E formed in the ice reservoir 7. Including, The first top guide rib 312a is a centerline of the ice making member 4 in which the ice I is generated so that the ice I colliding thereon may be deflected in the opposite direction to the ice discharge port E. Ice guide grill, characterized in that located in the direction toward the ice discharge port (E) in C1). The second highest guide according to claim 2 or 4, wherein the top guide rib 312 is located at a part of the guide part 300 farthest from the ice discharge port E formed in the ice reservoir 7. Rib 312b, The second top guide rib 312b is a centerline C2 of the ice making member 4 in which the ice I is generated so that the ice I colliding thereon is deflected in the direction of the ice discharge port E. ) Ice guide grill, characterized in that located in the opposite direction to the ice discharge port (E). The first guide rib 312a according to claim 2, wherein the top guide rib 312 is positioned at a portion of the guide portion 300 closest to the ice discharge port E formed in the ice reservoir 7; The second highest guide rib 312b and the first highest guide rib 312a and the second highest guide rib 312b positioned at a portion of the guide part 300 farthest from the ice discharge port E. A third highest guide rib 312c positioned in the guide part 300 between It is further included in the plurality of guide ribs 310, the height is higher than the lowest guide rib 311, is lower than the highest guide rib 312, the first highest guide rib (312a) and the second highest guide The intermediate guide ribs 313 or the third highest guide ribs 312c positioned in the guide part 300 between the ribs 312b are deflected in a direction opposite to the ice discharge port E by the ice I colliding therewith. Ice guide grill, characterized in that the deflection in the direction of the ice discharge port (E) in the center line (C) of the ice producing member (4) is generated so that the ice (I) can fall. A plurality of ice producing members 4 connected to the refrigerating cycle and generating ice I by heat exchange with a refrigerant flowing therein; The ice according to any one of claims 1 to 6, which is installed under the plurality of ice producing members 4 so as to adjust the falling direction of the ice I separated and dropped from the plurality of ice producing members 4. Guide grill 100; And An ice reservoir 7 installed below the ice guide grill 100 to store the ice I falling from the ice guide grill 100; Ice machine configured including.

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